DE10308654B4 - Data transmission system for connecting a controller with drives - Google Patents

Abstract

Data transmission system for connecting a control (1) with drives (8, 8a, 8b, 8c, 3a, 3b, 3c) in machine tools or production machines, the control (1) via an internal data bus (12) with at least one internal drive ( 8, 8a, 8b, 8c), the controller (1) being connectable to at least one external drive (3a, 3b, 3c) via an external data bus (2), characterized in that each data bus (2) has a data bus profile The data bus profile describes the content-related meaning of a message or a telegram of the data bus, whereby this relates to the data type used and the meaning such as an actual value, a setpoint, a control word or a status word, with the data bus profile additional at the beginning and end of a telegram Contains data that is used to coordinate the telegram traffic on the data bus (2) and the same data bus profiles are used on the internal data bus (12) as on an external data bus (2) are defined, with the data bus profiles of the internal data bus (12) and external data bus (2) being identical, with a parallel bus being provided as the internal data bus (12) and a Profibus, real-time Ethernet bus, USB bus as the external bus Bus, Firewire bus, Sercos bus or Profinet bus is provided.

Description

The invention relates to a data transmission system for connecting a controller with drives in tool or production machines, wherein the controller via an internal data bus with at least one internal drive is connectable, wherein the controller via an external data bus with at least one external drive is connectable.

Furthermore, the invention relates to a data transmission system for connecting a controller with drives in tool or production machines, wherein the controller via an internal data bus with at least one internal drive is connectable, wherein the internal drive via an external data bus with at least one external drive is connectable ,

For controlling and controlling motors or axes of tooling or production machines, whereby production machines also include robots or handling devices, two different control topologies are commercially used today. Thus, on the one hand, a so-called central control topology and, on the other hand, a so-called drive-based control topology is used.

In 1 is shown in the form of a block diagram exemplified a central control topology. This is characterized by having a controller 1 , which forms a closed structural unit, via an external data bus 2 with external drives 3a . 3b and 3c and optionally with yet another, for the sake of clarity, not shown drives for the exchange of data is connected. Every drive 3a . 3b and 3c contains control and / or control modules in the form of hardware and / or software modules, as well as an inverter module for controlling, controlling and powering an engine 5a . 5b or 5c , the z. B. each drives an axis of the tool or production machine. However, the converter module does not have to be integrated in the drive, but can also be connected to the drive in the form of an external module. The control and / or control modules and the converter modules are not shown for clarity.

To determine the Regelistgrößen the individual drives are connected to encoders, the sake of clarity, only one encoder 6a . 6b and 6c is shown. In addition, the drives 3a . 3b and 3c often still, as in 1 illustrated, with I / O modules (input / output modules) 4a . 4b and 4c connected to exchange data or signals. The I / O modules 4a . 4b and 4c but can also be an integral part of the respective drive. To control or regulate a motor of an axis of the machine sends z. B. the controller 1 over the external data bus 2 An axis setpoint (eg position setpoint or speed setpoint) to the external drive 3a which the engine 5a according to the specified axis position setpoint. At the central control topology form the controller 1 and the external drives structurally separate units, which via the external data bus 2 , the z. B. may be formed as a Profibus, are connected to each other for data exchange.

In 2 is shown in the form of a block diagram, another so-called drive-based control topology. In contrast to the central control topology, the control is based on the drive-based control topology 1 with a so-called internal drive 8th a structural unit acting as a drive-based control 7 referred to as. The control 1 and the internal drive 8th is for exchanging data with a so-called internal data bus 12 which z. B. may be formed as a PCI data bus (Peripheral Component Interconnect Bus) connected. The internal drive 8th is also with an I / O board 9 an engine 10 as well as a giver 11 connected. The drive 8th contains control and / or control modules in the form of hardware and / or software modules, as well as an inverter module for controlling, controlling and powering an engine 10 , the z. B. drives an axis of the tool or production machine. The converter module does not have to be in the drive either 8th can be integrated, but can also be connected in the form of an external module to the drive. Also, several converter modules can be present in one drive. The control and / or control modules and the converter modules are not shown for clarity. The regulation of the engine 10 takes place in the same way as in the central control topology, by setpoints from the controller 1 over the internal data bus 12 to the internal drive 8th be sent as a rule setpoint. Optionally, the drive-based control 7 also have several internal drives as in 8th shown.

For both control topologies, the actual values determined by the encoders and I / O modules are transferred via the data bus to the system. B. reported back to the controller for display purposes. At this point it should be noted that, of course, to the internal drive 8th Also, multiple motors, encoders or other I / O modules can be connected, allowing multiple axes from an internal drive 8th can be controlled or controlled simultaneously.

For cost and performance reasons, today increasingly drive-based Control topologies according to 2 used. However, the drive-based control topology has the inherent disadvantage that only a limited number of motors or drives with a drive-based control 7 can be controlled. A later extension by z. B. Connection of external drives to a drive-based control was previously not possible.

From the German patent application DE 19752015 A1 is known a saddle stitcher and a method for controlling the drive of the saddle stitcher.

From the German patent application DE 10147434 A1 For example, a system and method for diagnosing communication systems is known.

The invention is based on the object to ensure the same data interface from the user point of view, both in the central control topology as in the drive-based control topology to allow the user a simpler exchange of the two topologies.

This object is achieved by a data transmission system for connecting a controller with drives in tool or production machines, wherein the controller via an internal data bus with at least one internal drive is connectable, the controller via an external data bus with at least one external drive is connectable, the same data bus profiles are used on the internal data bus as defined on an external data bus, the data bus profiles of the internal data bus and the external data bus being identical, whereby a parallel bus is provided as the internal data bus and a Profibus, Real-Time Bus, is used as the external bus. Ethernet bus, USB bus, Firewire bus, Sercos bus or Profinet bus is provided.

Alternatively, this object is achieved by a data transmission system for connecting a controller with drives in tool or production machines, wherein the controller via an internal data bus with at least one internal drive is connectable, wherein the internal drive via an external data bus with at least one external drive is connectable in which the same data bus profiles are used on the internal data bus as defined on an external data bus, the data bus profiles of the internal data bus and the external data bus being identical, a parallel bus being provided as the internal data bus and a Profibus, real bus being used as the external bus. Time Ethernet bus, USB bus, Firewire bus, Sercos bus or Profinet bus is provided.

With the invention, scalability, i. E., Through a consistent logical view of the internal and external drives. H. The number of drives and I / O modules that can be connected to the controller and the use of drives and the integrated or externally connected I / O modules in the drives are significantly improved and simplified.

The unified configuration and programming view of internal and external drives, including their I / O modules, makes it possible to create applications or programs for the controller that are equally functional for both internal and external drives, and thus easily between the different control topologies are transferable. The user interface from the controller to internal and external drives is identical using the same data bus profiles. In addition, the internal drive or the internal drives as an external bus station, the z. B. may be present as a so-called slave modeled. This means that user interfaces that relate to the bus user, such. B. in Profibus the functions for activating / deactivating bus subscribers, remain identical. The interface between the controller and internal drives, which are modeled as bus subscribers, has the same system characteristics as the interface between the controller and external drives. This applies in particular to the timing and the setpoint / actual value exchange of data. The scalability is enhanced by the fact that additional drives and I / O modules can be homogeneously connected to a drive-based control via an external fieldbus.

Furthermore, it is possible by the invention to connect to drives-based controls and drives from foreign manufacturers via an external fieldbus in a simple manner.

Furthermore, it is made possible by the invention that, in the event that the external data bus ensures particularly secure data communication (eg PROFIsafe), it can do so without additional measures, due to the identical data bus profile of the internal and external data bus, also via the internal data bus , lets use. In addition, internal and external drives can have a close technological coupling as they can be set to have similar timing and behavior. The I / O modules integrated in the internal drive, which are usually used for internal drives, can be integrated in the same configuration and programming view as the I / O modules of external drives for central control topologies. This is a transparent Extensibility of I / O modules also possible over the external data bus.

It proves to be advantageous that the controller via an internal data bus with at least one internal drive is connectable, the controller via an external data bus with at least one external drive is connectable, the data bus profiles of internal data bus and external data bus are identical. This ensures easy connection of external drives to the controller.

It proves to be advantageous that the controller via an internal data bus with at least one internal drive is connectable, wherein the internal drive via an external data bus with at least one external drive is connectable, the data bus profiles of internal data bus and external data bus are identical. This ensures easy connection of external drives to the controller.

Furthermore, it proves to be advantageous that the controller can be connected to at least one internal drive via an internal data bus, wherein the controller can be connected to at least one external drive via an external data bus, wherein the internal drive can be modeled like an external bus subscriber. This has the advantage that also user interfaces that relate to the bus subscriber, such. B. in Profibus the functions for activating / deactivating bus subscribers, remain identical.

Furthermore, it proves to be advantageous that the controller can be connected to at least one internal drive via an internal data bus, wherein the internal drive can be connected to at least one external drive via an external data bus, whereby the internal drive can be modeled like an external bus subscriber. This has the advantage that also user interfaces that relate to the bus subscriber, such. B. in Profibus the functions for activating / deactivating bus subscribers, remain identical.

Furthermore, it proves to be advantageous that a parallel bus, in particular a PCI bus, is provided as the internal data bus. A PCI bus is a bus system that is very widespread in the art.

Furthermore, it proves to be advantageous that a Profibus, real-time Ethernet bus, USB bus, Firewire bus, Sercos bus, Profinet bus is provided as an external data bus. Profibus, Real-Time Ethernet bus, Firewire bus, Sercos bus, Profinet bus are widely used in the art bus systems.

In addition, it is advantageous if the I / O modules integrated in the internal drives or externally connected and the I / O modules of external drives are integrated with the same data bus profile. The E / B module of internal and external drives can therefore be treated identically by the user.

Furthermore, it proves to be advantageous if the configuration of the internal data bus, the controller and the internal drive from a logical point of view in a similar manner as the configuration of the external data bus.

Furthermore, it proves to be advantageous if the at least one internal drive and the at least one external drive have a close technological coupling, in particular clock synchronization and / or identical timing and / or a synchronized actual value detection.

Three embodiments of the invention is illustrated in the drawing and will be explained in more detail below. Showing:

1 a central control topology,

2 a drive-based control topology,

3 a drive-based control topology with additional decentralized drives,

4 an alternative drive-based control topology with additional decentralized drives,

5 a logical configuration and programming view of the connection of the drives to the controller,

6 a configuration of a drive axle,

7 a data bus profile and

8th a drive-based control topology with multiple internal drives.

In the block diagram according to 3 a physical view of the data transmission system according to the invention is shown. A drive-based control 7 is via an internal bus 12 , which is implemented in the embodiment as a PCI bus, with an internal drive 8th connected to the exchange of data. The drive 8th is with an external I / O board 9 a motor 10 and a giver 11 connected. The internal drive 8th includes control and control modules as well as for control and supply of the motor 10 one Inverter. The control and control modules and the inverter are not shown for clarity.

The control 1 , the internal data bus 12 as well as the internal drive 8th are realized in a common structural unit. The internal drive 8th can simultaneously control or regulate several motors or axes of the machine, but for the sake of clarity only one motor 10 , an I / O assembly 9 and a giver 11 is shown. The externally presented I / O module can also be an integral part of the internal drive 8th be.

To control the engine 10 is z. B. with the help of one within the controller 1 Position controller implemented an axis speed setpoint via the internal bus 12 a control module of the drive 8th set as the setpoint, then the engine 10 according to the axis setpoint to z. B. to move an axis of the machine to the appropriate axis position setpoint.

That's right 3 With 2 match. Across from 2 is however additionally in 3 the drive-based control 7 or the controller 1 via an external data bus 2 , which is executed in the embodiment as a Profibus, with the external drives 3a . 3b and 3c connected to the data exchange. Each of the drives 3a . 3b and 3c is each with a respective external I / O module 4a . 4b and 4c as well as a respective engine 5a . 5b and 5c and a respective donor 6a . 6b and 6c connected. For regulation z. B. the engine 5a is also here z. B. again from the controller 1 calculates an axis position setpoint and a control module within z. B. the external drive 3a fed, then with the help of a donor 6a generated actual value signal the motor 5a according to the target specification from the controller 1 , regulates. Conversely, of course, z. B. from the I / O modules signals z. B. for display purposes of the drives 3a . 3b and 3c for controlling 1 be transmitted. Of course, the external data bus 2 also be designed as a real-time Ethernet bus, Firewire bus, Sercos bus, Profinet bus or USB bus (Universal Serial Bus).

From the engineering and programming point of view, there is a uniform homogeneous logical view of the internal drive 8th and the external drives 3a . 3b and 3c desirable, because then no longer any difference between an internal drive for a project engineer, programmer or user 8th and an external drive 3a . 3b or 3c consists. Application or programs that originally z. B. for a central control topology according to 1 or a pure drive-based control topology according to 2 or on a drive-based control topology according to 3 can be used without much effort on one of the other topologies.

Each data bus has a so-called data bus profile. 7 shows an embodiment of a data bus profile. Purely physically, a telegram of the data bus is transmitted as a sequence of data bytes. With the data bus profile, the content is thus described the meaning of a message or a telegram, z. As the data type used (bytes, word) and meaning, z. B. actual value, setpoint, control word or status word). This ensures that transmitter and receiver different manufacturers interpret the telegram the same. An example would be z. B. a data bus profile, in which the first two bytes of a control word z. B. include a command to a drive and the bytes 3 to 6 z. B. include a speed setpoint. When Answertelegramm a drive z. For example, the first two bytes describe the state of the drive and bytes 3 to 6 describe a speed actual value. Optionally, a data bus may also have several different data bus profiles. A data bus profile also contains additional data at the beginning and at the end of a telegram, which serve to coordinate the telegram traffic on the data bus. This additional data is for clarity in 7 not shown.

According to the invention, the data bus profile used for the communication is now on the internal data bus 12 the same data bus profiles used as on the external data bus 2 are defined. In the embodiment according to 3 this means that the internal data bus running as a PCI bus 12 , as a result of its external data bus running as a Profibus 2 matching data bus profile, in principle like a Profibus works. The data interface between control 1 and internal drive 8th is thus defined identically as the data interface between the controller 1 and the drives 3a . 3b and 3c ,

In 5 is in the form of a block diagram in the embodiment resulting logical programming and projection view of the data interface between control 1 and internal drive 8th as well as between control 1 and the external drives 3a . 3b and 3c shown. All internal drives are logically connected to one, in 5 represented, so-called internal virtual Profibus 9a , All external drives are logically connected to one, in 5 represented, external Profibus 9b , In the embodiment, external and internal drives are dependent on the separate Profibus 9a and 9b , However, it is also possible to logically hang these on a common Profibus or to logically hang individual drives or groups of drives on their own Profibus. The control 1 works as one so-called master 18 while the drives work as slaves. The internal drive 8th is thus a slave 22 , the external drive 3a is a slave 19 , the external drive 3b is a slave 20 and the external drive 3c is a slave 21 assigned. The internal drive 8th Thus, from a logical or bustopological point of view, it only appears as another slave 22 the at the virtual internal PROFIBUS 9a hangs. On the external PROFIBUS 9b hang the slaves 19 . 20 and 21 ,

The projecting of the virtual internal Profibus 9a takes place in the same way as the external Profibus 9b , The setting variables specified by the integration frame conditions can shorten the configuration process, as it is possible to work with fixed settings here as an option. For the configuration of the internal virtual Profibus 9a There are only marginal differences compared to the configuration of the external Profibus 9b that relate to physical differences (eg transmission time eg on a PCI bus compared to eg a 12 Mbaud Profibus solution).

In the 5 used identifiers of the I / O modules, the motors and the encoder agree with those of 3 match. At this point it should again be noted that one to the external drive 8th connected I / O module or one in the internal drive 8th integrated I / O module, is integrated by the data transmission system according to the invention now just as homogeneous as the I / O modules of the decentralized drives 3a . 3b and 3c , This enables a scaled quantity framework of drive-related I / O modules to be realized.

6 shows a simple example of an advantageous configuration view resulting from the data transmission system according to the invention. In 6 In the context of a block diagram, for example, a schematic configuration surface is shown schematically by way of example. The machine axes and drives are symbolized by rectangular function blocks. A machine axis 15 with the name A1 should z. B. by an operator of the internal drive 8th be assigned to. This happens z. B. graphically by connecting the machine axis 15 with the internal drive 8th , By the resulting connection 16 Thus, the machine axis with the designation A1 is the external drive 8th assigned. Will now z. B. by the user entered a positioning command that z. B. the machine axis with the name A1 is to proceed by 20 mm, then the drive shaft corresponding to the external drive 8th is assigned to move 20 mm. Should not be the internal drive in the application example 8th assigned axis, but one to the external drive 3a assigned axis, so is the connection 16 to delete by the operator and accordingly the dashed line connection 17 manufacture. The configuration of an internal or external axis is therefore identical for the user.

In 4 a further alternative embodiment of the data transmission system according to the invention is shown in the form of a block diagram. This corresponds essentially 3 , only the external data bus 2 is not with the controller 1 but with the internal drive 8th connected. The data of the internal control 1 are then physically first to the internal drive 8th and from there via the external bus 2 to the external drives 3a . 3b and 3c forwarded and vice versa. With such a bus structure or network structure, the internal data bus can be extended externally in order to scale the quantity structure of the drives via a quasi "backplane bus". This can z. For example, the drive system internal communication system can be used to connect drive components (such as power parts, motors, encoders) for "backplane bus extension".

The external extension can be replaced by another medium such. As a real-time Ethernet bus, Firewire bus or Profibus be realized.

By doing that the data bus profile of the internal data bus 12 , the data bus profile of the external data bus 2 is identical, results again, depending on the external bus system used z. B. the in 5 presented uniform homogeneous logical configuration and programming view. Of course, the external data bus 2 also be designed as a USB bus (universal serial bus). In the 4 Identifiers used for the I / O modules, motors and encoders correspond to the identifiers of 3 ,

In the block diagram according to 8th a further embodiment of the data transmission system according to the invention is shown. A drive-based control 7 is via an internal bus 12 , which in the embodiment is implemented as a PCI bus, with internal drives 8a . 8b . 8c connected to the exchange of data. The drives 8a . 8b . 8c are each equipped with an internal I / O module integrated in the respective drive 9a . 9b or 9c a motor 10a . 10b or 10c and a giver 11a . 11b or 11c connected. The internal drives 8a . 8b and 8c each contain control and control modules that can be designed as hardware or software modules, as well as for controlling and powering the motor 10 an inverter. The control and control modules and the inverter is not shown for clarity. The control 1 , the internal data bus 12 as well as the internal drives 9a . 9b and 9c are realized in a common structural unit. As a result, the same data bus profiles on the internal data bus 12 The individual drives can be used as they are defined on an external data bus 8a . 8b and 8c be addressed uniformly, as if they were logically connected to an external data bus. The external data bus which physically in the embodiment according to 8th is not present, z. B. be defined as Profibus. Accordingly, the individual drives can be 8a . 8b . 8c as Profibus participant as z. B. address corresponding slaves by the user. If an extension in the form of a connected external data bus is actually physically performed at a later point in time, then the application or the program is on the control 1 still fully functional. The additional z. B. external drives are then simply in the form of z. B. additional slaves attached logically to the bus system.

Claims (6)

Data transmission system for connecting a controller ( 1 ) with drives ( 8th . 8a . 8b . 8c . 3a . 3b . 3c ) in tool or production machines, the controller ( 1 ) via an internal data bus ( 12 ) with at least one internal drive ( 8th . 8a . 8b . 8c ) is connectable, the controller ( 1 ) via an external data bus ( 2 ) with at least one external drive ( 3a . 3b . 3c ), characterized in that each data bus ( 2 ) has a data bus profile, wherein the data bus profile describes the meaning of content of a message or a telegram of the data bus, this being the type of data used, as well as the meaning such as an actual value, a setpoint, a control word or a status word, the data bus profile at the beginning and end of a telegram additional data necessary for coordinating the telegram traffic on the data bus ( 2 ) and contains the same data bus profiles on the internal data bus ( 12 ), as they are connected to an external data bus ( 2 ), the data bus profiles of the internal data bus ( 12 ) and external data bus ( 2 ) are identical, whereby as an internal data bus ( 12 ) a parallel bus is provided and as external bus Profibus, Real-Time Ethernet bus, USB bus, Firewire bus, Sercos bus or Profinet bus is provided. Data transmission system for connecting a controller ( 1 ) with drives ( 8th . 8a . 8b . 8c . 3a . 3b . 3c ) in tool or production machines, the controller ( 1 ) via an internal data bus ( 12 ) with at least one internal drive ( 8th . 8a . 8b . 8c ), whereby the internal drive ( 8th ) via an external data bus ( 2 ) with at least one external drive ( 3a . 3b . 3c ), characterized in that each data bus ( 2 ) has a data bus profile, wherein the data bus profile describes the meaning of content of a message or a telegram of the data bus, this being the type of data used, as well as the meaning such as an actual value, a setpoint, a control word or a status word, the data bus profile at the beginning and end of a telegram additional data necessary for coordinating the telegram traffic on the data bus ( 2 ) and contains the same data bus profiles on the internal data bus ( 12 ), as they are connected to an external data bus ( 2 ), whereby the data bus profiles of the internal data bus ( 12 ) and external data bus ( 2 ) are identical, whereby as an internal data bus ( 12 ) a parallel bus is provided and as an external bus a Profibus, real-time Ethernet bus, USB bus, Firewire bus, Sercos bus or Profinet bus is provided. Data transmission system according to one of the preceding claims, characterized in that in the internal drives ( 8th . 8a . 8b . 8c integrated or externally connected I / O modules ( 9 . 9a . 9b . 9c ) as well as the I / O modules ( 4a . 4b . 4c ) of external drives ( 3a . 3b . 3c ) are integrated with the same data bus profile. Data transmission system according to one of the preceding claims, characterized in that the configuration of the internal data bus ( 12 ), the controller ( 1 ) and the internal drive ( 8th . 8a . 8b . 8c ) from a logical point of view in a similar way as the configuration of the external data bus ( 2 ) he follows. Data transmission system according to one of the preceding claims, characterized in that the at least one internal drive and the at least one external drive ( 8th . 8a . 8b . 8c . 3a . 3b . 3c ) have a close technological coupling, in particular clock synchronization and / or identical timing and / or a synchronized actual value acquisition. Data transmission system according to one of the preceding claims, characterized in that a PCI bus is provided as a parallel bus.

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